Devices and processes for detecting surface defects

Abstract

A device for detecting defects on at least one surface may include: a source configured to emit electromagnetic radiation in at least one first spectral band; a video camera sensitive in at least one second spectral band; and a diffuser configured to intercept at least part of the electromagnetic radiation emitted by the source and to make more homogeneous a spatial distribution of intensity of the electromagnetic radiation over the at least one surface. The source may be further configured to project a beam of the electromagnetic radiation onto the at least one surface. An intersection of the at least one first spectral band and the at least one second spectral band may determine a spectral working band. A bandwidth of the spectral working band may be less than or equal to 200 nanometers (nm). The spectral working band may be between 300 nm and 1,100 nm.

Claims

1. A process for detecting painting defects in painted elements, the process comprising: a) obtaining an electromagnetic radiation source configured to emit electromagnetic radiation in a first spectral band; b) projecting a beam of the electromagnetic radiation on at least one surface to be inspected; c) obtaining a video camera, sensitive in a second spectral band, wherein a spectral working band of the process is the first spectral band if the first spectral band is entirely contained within the second spectral band, wherein the spectral working band of the process is the second spectral band if the second spectral band is entirely contained within the first spectral band, and wherein the spectral working band of the process is an intersection of the first and second spectral bands if the first and second spectral bands overlap; and d) arranging the video camera so as to obtain images of the at least one surface to be inspected in an incidence zone of the beam of the electromagnetic radiation emitted by the source; wherein: e) a diffuser is obtained, the diffuser configured to make more homogeneous a spatial distribution of intensity of the electromagnetic radiation emitted by the source; f) the diffuser is arranged so as to intercept at least part of the electromagnetic radiation emitted by the source and to make more homogeneous the spatial distribution of the intensity; g) an intensity alternator is obtained, the intensity alternator configured to obtain a spatial arrangement of the electromagnetic radiation that alternates high-intensity electromagnetic radiation zones with low-intensity electromagnetic radiation zones; h) the intensity alternator is arranged so as to intercept, after the diffuser, the electromagnetic radiation emitted by the source so as to create, on the at least one surface to be inspected, the high-intensity electromagnetic radiation zones alternating with the low-intensity electromagnetic radiation zones; i) images of the spatial arrangement of the intensity of the electromagnetic radiation on the at least one surface to be inspected are obtained from the video camera; and j) the painting defects appearing as lower intensity spots in the high-intensity electromagnetic radiation zones are identified, the painting defects appearing as higher intensity spots in the low-intensity electromagnetic radiation zones are identified, or the painting defects appearing as lower intensity spots in the high-intensity electromagnetic radiation zones and the painting defects appearing as higher intensity spots in the low-intensity electromagnetic radiation zones are identified.

2. The process of claim 1, wherein the spectral working band of the process is comprised between 300 nanometers (nm) and 1,100 nm, and wherein the spectral working band of the process has a bandwidth less than or equal to 200 nm.

3. The process of claim 2, wherein the spectral working band of the process has a bandwidth less than or equal to 50 nm.

4. The process of claim 2, wherein the spectral working band of the process has a bandwidth less than or equal to 20 nm.

5. The process of claim 2, wherein the spectral working band of the process is comprised between 800 nm and 900 nm.

6. The process of claim 2, wherein the spectral working band of the process is comprised between 810 nm and 860 nm.

7. The process of claim 2, wherein the spectral working band of the process is comprised between 825 nm and 835 nm.

8. The process of claim 2, wherein the spectral working band of the process is comprised between 840 nm and 860 nm.

9. The process of claim 2, wherein the high-intensity electromagnetic radiation zones alternating with the low-intensity electromagnetic radiation zones have a pitch less than or equal to 20 millimeters (mm).

10. The process of claim 9, wherein the pitch is less than or equal to 4 mm.

11. The process of claim 2, wherein the spectral working band of the process comprises two or more distinct spectral bands.

12. The process of claim 1, wherein the spectral working band of the process is comprised between 750 nanometers (nm) and 1,050 nm, and wherein the spectral working band of the process has a bandwidth less than or equal to 200 nm.

13. The process of claim 12, wherein the spectral working band of the process has a bandwidth less than or equal to 50 nm.

14. The process of claim 12, wherein the spectral working band of the process has a bandwidth less than or equal to 20 nm.

15. The process of claim 12, wherein the spectral working band of the process is comprised between 800 nm and 900 nm.

16. The process of claim 12, wherein the spectral working band of the process is comprised between 810 nm and 860 nm.

17. The process of claim 12, wherein the spectral working band of the process is comprised between 825 nm and 835 nm.

18. The process of claim 12, wherein the spectral working band of the process is comprised between 840 nm and 860 nm.

19. The process of claim 12, wherein the high-intensity electromagnetic radiation zones alternating with the low-intensity electromagnetic radiation zones have a pitch less than or equal to 20 millimeters (mm).

20. The process of claim 19, wherein the pitch is less than or equal to 4 mm.

21. The process of claim 12, wherein the spectral working band of the process comprises two or more distinct spectral bands.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The invention will be better understood by the following specification provided for illustration purposes only, thus without limitation, of a preferred embodiment illustrated in the accompanying drawings in which:

(2) FIG. 1A shows a perspective view of the device according to the invention with the projection of a plurality of high-intensity electromagnetic radiation lines, alternating with low-intensity electromagnetic radiation lines, on the surface to be inspected;

(3) FIG. 1B shows the distribution of the electromagnetic radiation intensity on a line L1 intersecting such high-intensity electromagnetic radiation lines and low-intensity electromagnetic radiation lines in the center part of the beam projected by the source on the surface to be inspected.

(4) FIG. 2 shows a perspective view of an embodiment of the device according to the invention with an electromagnetic radiation source to which two video cameras are connected;

(5) FIG. 3 shows a sectional view of the same source as FIG. 2;

(6) FIG. 4 shows a part of the electromagnetic spectrum with a first spectral band of the electromagnetic radiation source, a second spectral band wherein the video camera is sensitive, and the spectral working band obtained by the intersection of the first and second spectral bands, said spectral working band coinciding in this case with the second spectral band.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT OF THE PRESENT INVENTION

(7) The human eye visible electromagnetic radiation ranges from about 400 nm (purple) to 750 nm (red).

(8) The not-visible radiation beyond the red is named as infrared radiation.

(9) The infrared radiation is categorized in non-thermal infrared (from 750 nm to about 2000 nm) and thermal infrared (beyond 2000 nm).

(10) A body being at room temperature (about 300 K) emits infrared radiation in the thermal infrared band, but not in the non-thermal infrared band, and thus under 2000 nm. Normal video cameras with CCD or CMOS sensor are sensitive in the 300 nm-1100 nm band and can thus see in the non-thermal infrared region to which the human eye is not sensitive.

(11) This property is used to see in the dark, by using an infrared illuminator, for example, a suitable light-emitting diode (LED).

(12) In the field of the non-thermal infrared, an infrared source emits infrared radiation which is reflected by an object and then captured by the sensor of a video camera, such as in the visible.

(13) From about 2500-3000 nm the room temperature bodies emit electromagnetic radiation and such emitted radiation is added to the possibly reflected radiation.

(14) The radiation, emitted by a source and addressed to a surface to be inspected, is partly specularly reflected by the surface and partly diffusely reflected in all the directions.

(15) The share of radiation diffusely reflected in all the directions increases as the surface roughness of the surface to be inspected increases.

(16) It has surprisingly been found that, while the deflectometric techniques are based on the radiation specularly reflected by the surface to be inspected, the radiation diffusely reflected in all the directions can allow detecting surface and painting defects with a better signal-to-noise ratio and thus a better likelihood of correctly detecting the defect.

(17) In reference to FIGS. 1 to 3, the device according to the invention for detecting defects on surfaces to be inspected, preferably painted surfaces, is shown, comprising a source 1 adapted to emit electromagnetic radiation in at least one first spectral band B1 (FIG. 4), in order to project a beam of electromagnetic radiation onto at least one surface to be inspected 6, preferably a painted surface; a video camera 2 sensitive in at least one second spectral band B2 (FIG. 4) and arranged so that to obtain images of said at least one surface to be inspected 6 in the zone wherein the electromagnetic radiation beam emitted by the source 1 is projected, a diffuser 3, adapted to intercept at least part of the electromagnetic radiation emitted by the source 1 and to make more homogeneous the spatial distribution of the intensity of said electromagnetic radiation on said at least one surface to be inspected 6.

(18) The source 1 can be a normal incandescent lamp or a neon or LED lamp or any other source, such as for example a laser, emitting in a first spectral band B1 which overlaps at least partly to a second spectral band B2 wherein the video camera 2 is sensitive.

(19) The intersection between said first spectral band B1 and said second spectral band B2 establishes a spectral working band BL wherein the device is operative.

(20) One of the first and second spectral bands B1 or B2 can be completely comprised in the other one, whereby the spectral working band BL corresponds to one of the two bands. For example, it is possible that, as in the example of FIG. 4, the second spectral band B2 wherein the video camera 2 is sensitive is completely comprised in the first spectral band B1 wherein the source 1 emits, whereby the spectral working band BL is corresponding to the second spectral band B2 of the video camera 2.

(21) Said spectral working band can also comprise several bands, for example one in the visible and one in the non-thermal infrared.

(22) This can be obtained by arranging suitable filters in front of the source 1 or the video camera 2.

(23) The video camera 2 can comprise a normal black and white video camera with CCD (charge coupled device) or CMOS (complementary metal-oxide semiconductor) sensor which is sensitive in a spectral band from 300 nm to 1100 nm, thus also comprising a part of non-thermal infrared, to which a filter is put before in order to select the desired spectral working band BL.

(24) It has been found that better results can be obtained if such spectral working band BL is adequately narrow.

(25) For this reason the spectral working band BL has a bandwidth less than or equal to 200 nm, and is between 300 nm and 1100 nm.

(26) As visible in FIG. 3, the diffuser 3 can comprise an opaline or a milky semitransparent element interposed between the source 1 and the surface to be inspected 6.

(27) While a normal lamp or light source lightens a surface with non-homogeneous intensity, the device according to the invention obtains better results when the intensity of the emitted electromagnetic radiation is homogeneously distributed over the surface to be inspected.

(28) This can be obtained by moving the source away from the surface to be inspected, but the intensity of the electromagnetic radiation decreases with the well known square of the distance law.

(29) The diffuser 3 helps to make more homogeneous the distribution of the intensity of the electromagnetic radiation emitted by the source 1.

(30) Better results are obtained when the spectral working band BL is adequately narrow and has therefore a bandwidth lower than or equal to 50 nm, even better if said spectral working band BL has a bandwidth lower than or equal to 20 nm.

(31) It has also been found that better results are obtained if such a spectral working band BL is arranged in the non-thermal infrared, for example if the spectral working band BL is between 750 nm and 1050 nm.

(32) Even better if said spectral working band BL is between 800 nm and 900 nm, thus adequately far from the visible radiation.

(33) Better if said spectral working band BL is between 810 nm and 860 nm.

(34) Based on the experiments carried out, it has been found that the optimum is obtained in two spectral working bands BL, the first one between 825 nm and 835 nm and the second one between 840 nm and 860 nm.

(35) As it has been seen from the mentioned previous art, the currently existing devices often project onto the surface to be inspected a plurality of light and dark lines, which alternate a high light intensity and a low light intensity.

(36) The presence of lines or however of a spatial arrangement alternating high-intensity electromagnetic radiation zones with low-intensity electromagnetic radiation zones onto the surface to be inspected 6 allows better results to be obtained, also in the device according to the invention.

(37) For this reason the device according to the invention comprises an intensity alternator 4 adapted to intercept, after the diffuser 3, the electromagnetic radiation emitted by the source 1 and to generate, on said at least one surface to be inspected 6, a spatial arrangement 5 of the electromagnetic radiation comprising high-intensity electromagnetic radiation zones alternating with low-intensity electromagnetic radiation zones.

(38) Preferably (FIG. 1A and FIG. 1B) such a spatial arrangement 5 of the intensity distribution of the electromagnetic radiation emitted by the source comprises a plurality of high-intensity electromagnetic radiation lines Z1 alternating with low-intensity electromagnetic radiation lines Z2, said lines Z1 and Z2 being substantially parallel.

(39) Other spatial arrangements, such as for example circular concentric lines, are of course possible.

(40) In said spatial arrangement 5, which is projected onto the surface to be inspected, the alternation of high-intensity electromagnetic radiation lines Z1 with low-intensity electromagnetic radiation lines Z2 creates a repetitive figure, wherein the pitch P1 (FIG. 1B) of such a repetition is preferably small, lower than or equal to 20 mm, better if lower than or equal to 4 mm.

(41) The size of such a pitch P1 also depends on the minimum size of the defect desired to be detected.

(42) It is of course possible that the duty-cycle varies between 5% and 95%, i.e. that the thickness of the high-intensity electromagnetic radiation lines Z1 is different from that of the low-intensity electromagnetic radiation lines Z2, specifically that the thickness of the high-intensity electromagnetic radiation lines Z1 is smaller than that of the low-intensity electromagnetic radiation lines.

(43) It is preferable that, by also using particular focusing optics, the electromagnetic radiation emitted from the source is adequately diffused such that the passage from a high-intensity electromagnetic radiation zone to an adjacent low-intensity electromagnetic radiation zone is substantially stepped and the intensity of the electromagnetic radiation in the high-intensity electromagnetic radiation zone is homogeneous.

(44) Referring to FIG. 1 it can be seen that, in the center portion of the beam of electromagnetic radiation projected by the source 1 and in the spectral working band BL, the distribution of the electromagnetic radiation intensity over a line L1 intersecting such high-intensity electromagnetic radiation zones (Z1) and low-intensity electromagnetic radiation zones (Z2) is preferably a substantially square wave function, with steep rising edge and falling edge and substantially uniform values in the high-intensity electromagnetic radiation zone Z1 and in the low-intensity electromagnetic radiation zone Z2.

(45) Both in the low-intensity electromagnetic radiation zones Z2 and the high-intensity electromagnetic radiation zones Z1 the ambient lighting can create a decrease in contrast and saturation and, if not arranged homogeneously, can determine a lower homogeneity of the radiation intensity.

(46) For a better sensitivity of the device to defects, the video camera is preferred not to reach the saturation, when observing the high-intensity electromagnetic radiation zone Z1 on a defect-free surface to be inspected.

(47) The spectral working band may comprise two or more different spectral bands and the image acquisition may occur simultaneously on said spectral bands or in temporal succession (first on a band and then on another band).

(48) The images obtained on different bands are overlapped or processed together in accordance with convenient mathematical algorithms, in order to improve the signal-to-noise ratio and increase the likelihood of detecting possible defects being on the surface to be inspected.

(49) Conversely to the devices based on deflectometric techniques, in the device according to the invention the relative position of the source and the video camera is not relevant.

(50) In the rendering of FIG. 2, source 1 and video camera 2 are close together and mutually constrained.

(51) The video camera 2 and the source 1 are preferably arranged along a direction normal to the at least one surface to be inspected 6. Such an arrangement is not usually adopted in the deflectometric techniques since, in order to obtain better sensitivity, it is preferred that the electromagnetic radiation emitted by the source impinge onto the surface to be inspected with an angle of at least 45° with respect to the normal, whereas the video camera is arranged in the specular direction with respect to the incidence direction of the electromagnetic radiation.

(52) In its operation, the source 1 projects onto the at least one surface to be inspected 6 a beam of electromagnetic radiation having homogeneous high-intensity electromagnetic radiation zones Z1 alternating with low-intensity electromagnetic radiation zones Z2, for example, a strip spatial arrangement 5.

(53) The video camera 2 captures the at least one surface to be inspected 6 in the center portion of the beam projected by the source 1.

(54) The presence of a defect locally alters the homogeneity of the radiation intensity or locally deforms the spatial arrangement, thus allowing the defect to be detected.

(55) For example, the defect can appear as lower intensity spots in the high-intensity electromagnetic radiation zones Z1 and/or as higher intensity spots in the low-intensity electromagnetic radiation zones Z2, or as a distortion of the edges wherein the passage between a high-intensity electromagnetic radiation zone Z1 and a low-intensity electromagnetic radiation zone Z2 occurs.

(56) Preferably, the at least one surface to be inspected 6 runs with respect to the device according to the invention such that the scan of the whole at least one surface to be inspected 6 can be obtained quickly.

(57) An electronic device for image analysis can easily and automatically detect the defects with high reliability.

(58) The present invention also wants to protect a process for detecting defects on surfaces to be inspected, preferably on painted surfaces, comprising the following steps:

(59) a) obtaining an electromagnetic radiation source 1 adapted to emit electromagnetic radiation in at least one first spectral band B1;

(60) b) projecting a beam of electromagnetic radiation on at least one surface to be inspected 6;

(61) c) obtaining a video camera 2 sensitive in at least one second spectral band B2, the intersection between said first spectral band B1 and said second spectral band B2 determining a non-null spectral working band BL;

(62) d) arranging the video camera 2 so as to obtain images of said at least one surface to be inspected 6 in the incidence zone of the electromagnetic radiation beam emitted by the source 1;

(63) e) obtaining a diffuser 3 adapted to make more homogeneous the spatial distribution of the intensity of the electromagnetic radiation emitted by the source 1;

(64) f) arranging the diffuser 3 so that to intercept at least part of the electromagnetic radiation emitted by the source 1 and to make more homogeneous its intensity;

(65) g) obtaining an intensity alternator 4 adapted to obtain a spatial arrangement 5 of the electromagnetic radiation alternating high-intensity electromagnetic radiation zones Z1 with low-intensity electromagnetic radiation zones Z2;

(66) h) arranging the intensity alternator 4 so to intercept, after the diffuser 3, the electromagnetic radiation emitted by the source 1 so as to create, on the surface to be inspected 6, high-intensity electromagnetic radiation zones Z1 alternating with low-intensity electromagnetic radiation zones Z2;

(67) i) obtaining images of the spatial arrangement 5 of the intensity of the electromagnetic radiation over said at least one surface to be inspected 6 from the video camera 2;

(68) j) identifying defects appearing as lower intensity spots in the high-intensity electromagnetic radiation zones Z1 and/or appearing as higher intensity spots in the low-intensity electromagnetic radiation zones Z2.

(69) It is of course possible that the process comprises the image acquisition on different spectral working bands and the processing of said images by means of mathematical algorithms adapted to increase the signal-to-noise ratio and the likelihood of detecting a defect that might be on the surface to be inspected.

(70) Thanks to the electromagnetic radiation being distributed homogeneously at least in the high-intensity electromagnetic radiation zones Z1, the detection of the painting or geometric and aesthetic defects is made easier with respect to other today existing devices and the signal-to-noise ratio is improved, with higher reliability of the device.

(71) The inspection can, of course, be expected to be done in the visible spectrum by a human operator, thus without a video camera 2.

(72) The surfaces that can be inspected are not only painted surfaces, but also surfaces having been subjected or not to a surface treatment, such as resin deposition or even a transparent coating.

(73) It is also possible, but not preferable, that the device according to the invention does not use an intensity alternator in order to have high-intensity electromagnetic radiation zones alternating with low-intensity electromagnetic radiation zones, but simply a diffuser in order to have an homogeneous distribution of the intensity of the electromagnetic radiation emitted by the source over the surface to be inspected.

(74) An adequate homogeneity of the electromagnetic radiation distribution over the surface to be inspected is often enough.

(75) An advantageous characteristic of the invention is that, conversely to the devices based on the deflectometric technique, the device according to the invention allows wide freedom in the arrangement of the video camera and the source.